A graviton statistics approach to dark energy, inflation and black holes
We derive two new equations of quantum gravity and combine them with reinterpretations of previously proposed concepts of dark energy, inflation and black holes into a theory which may be a first step toward a comprehensive description of all three phenomena. The resulting theory also predicts new t...
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Zusammenfassung: | We derive two new equations of quantum gravity and combine them with
reinterpretations of previously proposed concepts of dark energy, inflation and
black holes into a theory which may be a first step toward a comprehensive
description of all three phenomena. The resulting theory also predicts new
tests which can be experimentally checked within just a few years. The two new
equations are : A) a creation equation to give stimulated emission for any
surface filled with gravitons, pulling energy from a background, and B) the
association of an outgoing soliton wave of gravitons, a "shell front" with a
large Lorentz factor derived from the uncertainties in both space and time.
These new equations are combined with the common notions of an all-pervasive
background of gravitons at the Planck limit, the "Planck sea"; the
identification of the thermodynamic limit with the emission of gravitons in a
"shell front", i.e. what is usually called the entropy of black holes is
identified with the outgoing gravitons; the concept of black holes as a
membrane full of gravitons at a large Lorentz factor, the "Planck shell"; the
emission of gravitons created in a "horizon shell" during inflation. These
equations result in stimulated emission of gravitons by the interaction with
the background, the "Planck sea", to describe dark energy, black holes, the
inflationary period of the universe, and the arrow of time. These proposals
lead to gravitational waves constituting dark energy. These waves should be
detectable within a few years with pulsar timing arrays. These gravitational
waves can be characterized as uncorrelated solitons, and should also be
detectable with ultra-high precision lunar laser ranging, as well as with
correspondingly precise clocks. The extremely high, but finite Lorentz factor
for signal propagation may be expected to have further consequences in particle
interactions. |
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DOI: | 10.48550/arxiv.1205.4016 |